1. Copyright © Cengage Learning. All rights reserved. 8 Further Applications of Integration

2. Copyright © Cengage Learning. All rights reserved. 8.4 Applications to Economics and Biology

3. 33 In this section we consider some applications of integration to economics (consumer surplus) and biology (blood flow, cardiac output).

4. 44 Consumer Surplus

5. 55 Recall that the demand function p(x) is the price that a company has to charge in order to sell x units of a commodity. Usually, selling larger quantities requires lowering prices, so the demand function is a decreasing function. The graph of a typical demand function, called a demand curve, is shown in Figure 1. If X is the amount of the commodity that is currently available, then P = p(X) is the current selling price. Figure 1 A typical demand curve

6. 66 Consumer Surplus We divide the interval [0, X ] into n subintervals, each of length  x = X/n, and let x i * = x i be the right endpoint of the i th subinterval, as in Figure 2. If, after the first x i – 1 units were sold, a total of only x i units had been available and the price per unit had been set at p(x i ) dollars, then the additional  x units could have been sold (but no more). Figure 2

7. 77 Consumer Surplus The consumers who would have paid p(x i ) dollars placed a high value on the product; they would have paid what it was worth to them. So, in paying only P dollars they have saved an amount of (savings per unit) (number of units) = [p(x i ) – P]  x

8. 88 Consumer Surplus Considering similar groups of willing consumers for each of the subintervals and adding the savings, we get the total savings: [p(x i ) – P]  x (This sum corresponds to the area enclosed by the rectangles in Figure 2.) Figure 2

9. 99 Consumer Surplus If we let n , this Riemann sum approaches the integral which economists call the consumer surplus for the commodity. The consumer surplus represents the amount of money saved by consumers in purchasing the commodity at price P, corresponding to an amount demanded of X.

10. 10 Consumer Surplus Figure 3 shows the interpretation of the consumer surplus as the area under the demand curve and above the line p = P. Figure 3

11. 11 Example 1 The demand for a product, in dollars, is p = 1200 – 0.2x – 0.0001x 2 Find the consumer surplus when the sales level is 500. Solution: Since the number of products sold is X = 500, the corresponding price is P = 1200 – (0.2)(500) – (0.0001)(500) 2 = 1075

12. 12 Therefore, from Definition 1, the consumer surplus is [p(x) – P] dx = (1200 – 0.2x – 0.0001x 2 – 1075)dx = (125 – 0.2x – 0.0001x 2 ) dx = 125x – 0.1x 2 – (0.0001) = (125)(500) – (0.1)(500) 2 – = $33,333.33 Example 1 – Solution cont’d

13. 13 Blood Flow

14. 14 We have discussed the law of laminar flow: which gives the velocity v of blood that flows along a blood vessel with radius R and length l at a distance r from the central axis, where P is the pressure difference between the ends of the vessel and  is the viscosity of the blood. Now, in order to compute the rate of blood flow, or flux (volume per unit time), we consider smaller, equally spaced radii r 1, r 2,.... Blood Flow

15. 15 The approximate area of the ring (or washer) with inner radius r i – 1 and outer radius r i is 2  r i  rwhere  r = r i – r i –1 (See Figure 4.) Blood Flow Figure 4

16. 16 If  r is small, then the velocity is almost constant throughout this ring and can be approximated by v(r i ). Thus the volume of blood per unit time that flows across the ring is approximately (2  r i  r) v(r i ) = 2  r i v(r i )  r and the total volume of blood that flows across a cross-section per unit time is about 2  r i v(r i )  r This approximation is illustrated in Figure 5. Blood Flow Figure 5

17. 17 Notice that the velocity (and hence the volume per unit time) increases toward the center of the blood vessel. The approximation gets better as n increases. When we take the limit we get the exact value of the flux (or discharge), which is the volume of blood that passes a cross-section per unit time: Blood Flow

18. 18 Blood Flow

19. 19 The resulting equation is called Poiseuille’s Law; it shows that the flux is proportional to the fourth power of the radius of the blood vessel. Blood Flow

20. 20 Cardiac Output

21. 21 Figure 6 shows the human cardiovascular system. Cardiac Output Figure 6

22. 22 Blood returns from the body through the veins, enters the right atrium of the heart, and is pumped to the lungs through the pulmonary arteries for oxygenation. It then flows back into the left atrium through the pulmonary veins and then out to the rest of the body through the aorta. The cardiac output of the heart is the volume of blood pumped by the heart per unit time, that is, the rate of flow into the aorta. The dye dilution method is used to measure the cardiac output. Cardiac Output

23. 23 Dye is injected into the right atrium and flows through the heart into the aorta. A probe inserted into the aorta measures the concentration of the dye leaving the heart at equally spaced times over a time interval [0, T ] until the dye has cleared. Let c(t) be the concentration of the dye at time t. If we divide [0, T ] into subintervals of equal length  t, then the amount of dye that flows past the measuring point during the subinterval from t = t i–1 to t = t i is approximately (concentration) (volume) = c(t i ) (F  t) where F is the rate of flow that we are trying to determine. Cardiac Output

24. 24 Thus the total amount of dye is approximately c(t i )F  t = F c(t i )  t and, letting n , we find that the amount of dye is A = F c(t) dt Thus the cardiac output is given by where the amount of dye A is known and the integral can be approximated from the concentration readings. Cardiac Output

25. 25 Example 2 A 5-mg bolus of dye is injected into a right atrium. The concentration of the dye (in milligrams per liter) is measured in the aorta at one-second intervals as shown in the chart. Estimate the cardiac output.

26. 26 Example 2 – Solution Here A = 5,  t = 1, and T = 10. We use Simpson’s Rule to approximate the integral of the concentration: c(t) dt  [0 + 4(0.4) + 2(2.8) + 4(6.5) + 2(9.8) + 4(8.9) + 2(6.1) + 4(4.0) + 2(2.3) + 4(1.1) + 0]  41.87 Thus Formula 3 gives the cardiac output to be   0.12 L/s = 7.2 L/min